The effect of allopurinol administration on mitochondrial respiration and gene expression of xanthine oxidoreductase, inducible nitric oxide synthase, and inflammatory cytokines in selected tissues of broiler chickens.

Birds have a remarkable longevity for their body size despite an increased body temperature, higher metabolic rate, and increased blood glucose concentrations compared to most mammals. As the end-product of purine degradation, uric acid (UA) is generated in the xanthine/hypoxanthine reactions catalyzed by xanthine oxidoreductase (XOR). In the first study, Cobb × Cobb broilers (n = 12; 4 weeks old) were separated into 2 treatments (n = 6); control (CON) and allopurinol (AL) 35 mg/kg BW (ALLO).

Effects of a Phytogenic Feed Additive Versus an Antibiotic Feed Additive on Oxidative Stress in Broiler Chicks and a Possible Mechanism Determined by Electron Spin Resonance.

Phytogenic feed additives are plant-derived products used in poultry feeding to improve overall performance of broilers. In this study, 588 one day-old Cobb 500 chicks were fed one of four diets and housed on either dirty or clean litter for 3wks. Treatments included: Group I: commercial diet with no additive and housed on clean litter; Group II: commercial diet with no additive and housed on dirty litter; Group III: commercial diet with a 0.

The effects of allopurinol, uric acid, and inosine administration on xanthine oxidoreductase activity and uric acid concentrations in broilers.

The purpose of these studies was to determine the effects of uric acid (UA) and inosine administration on xanthine oxidoreductase activity in broilers. In experiment one, 25 broilers were assigned to 5 treatment groups: control, AL (25 mg of allopurinol/kg of body mass), AR (AL for 2 wk followed by allopurinol withdrawal over wk 3), UAF (AL plus 6.25 g of UA sodium salt/kg of feed), and UAI (AL plus 120 mg of UA sodium salt injected daily).

Determination of xanthine oxidoreductase activity in broilers: effect of pH and temperature of the assay and distribution in tissues.

Xanthine oxidoreductase (XOR) is the enzyme responsible for the synthesis of uric acid, which exists primarily in the dehydrogenase form in birds. Uric acid is the major end product of the metabolism of nitrogen-containing compounds in birds and it functions as an antioxidant to reduce oxidative stress. Despite the importance of this enzyme, the tissue distribution of XOR in physiologically normal chickens is not well known.

Effects of allopurinol on uric acid concentrations, xanthine oxidoreductase activity and oxidative stress in broiler chickens.

The purpose of this study was to determine the effects of allopurinol (AL) on xanthine oxidoreductase (XOR) activity and uric acid (UA) levels in chickens. Thirty 5-week-old broilers were divided into three groups and fed 0 (control), 25 (AL25) or 50 (AL50) mg AL per kg of body mass for 5 weeks. Chicks were weighed twice weekly and leukocyte oxidative activity (LOA) and plasma purine levels were determined weekly in five birds per group.

Inosine ameliorates the effects of hemin-induced oxidative stress in broilers.

The objective of these studies was to determine whether inosine, a precursor of the antioxidant uric acid, can ameliorate hemin-induced oxidative stress. Dietary inclusion of inosine was begun either before or after hemin-induced oxidative stress. Broilers (4 weeks) were divided into four treatment groups (Control, Hemin, Inosine, Hemin/Inosine).

Classic and non-classic progesterone receptors are both expressed in human spermatozoa.

Progesterone is one of the physiological inducers of the acrosome reaction in mammalian spermatozoa. The receptor that responds to progesterone is not yet identified, and its properties differ in many aspects from the properties of the classic nuclear progesterone receptor, suggesting the participation of a novel or non-classic receptor. In this study, we investigated the expression of a novel progesterone-binding protein (hmPR1/PGMRC1) and its ortholog (hmPR2/PGMRC2), which have previously been identified in liver microsomes and are considered receptor candidates, along with the nuclear progesterone receptor.

Porcine spermatozoa contain more than one membrane progesterone receptor.

Progesterone has been shown to be a physiologically relevant inducer of the sperm acrosome reaction. A novel protein intrinsic to microsomal membranes, membrane progesterone receptor (mPR, now termed progesterone membrane receptor component 1, PGMRC1) that binds progesterone with high affinity has been cloned from porcine liver previously, and corresponding antibodies mitigate the progesterone induced acrosome reaction. In this study we aimed at the localization of mPR in porcine spermatozoa.

Mineralocorticoid receptor antagonists do not block rapid ERK activation by aldosterone.

Aldosterone can elicit rapid nongenomic effects both in vivo and in vitro, often mediated by signal transduction cascades. However, it is not understood how these rapid effects are initiated. In this study we show that aldosterone leads to rapid activation of mitogen activated protein kinases ERK1/2 in the cortical collecting duct cell line M-1.

Nongenomic steroid action: controversies, questions, and answers.

Steroids may exert their action in living cells by several ways: 1). the well-known genomic pathway, involving hormone binding to cytosolic (classic) receptors and subsequent modulation of gene expression followed by protein synthesis. 2).

Allantoin, the oxidation product of uric acid is present in chicken and turkey plasma.

Urate oxidase is not present in birds yet allantoin, a product of this enzyme, has been measured in birds. Studies were designed to compare the concentrations of plasma purine derivatives in chickens and turkeys fed inosine-supplemented diets. The first study consisted of 12 male chicks that were fed diets supplemented with 0.

Aldosterone- and progesterone-membrane-binding proteins: new concepts of nongenomic steroid action.

n the classical theory of steroid action steroids penetrate into cells and bind to intracellular receptors resulting in modulation of nuclear transcription and protein synthesis within hours. In addition, rapid actions of steroids have been identified, which are incompatible with the classic model of steroid action. Specific binding sites for aldosterone and progesterone have been reported in membrane preparations of liver, vascular smooth muscle cells and kidney.

Nongenomic effects of aldosterone: cellular aspects and clinical implications.

Nongenomic action of aldosterone has been observed in many cell types which often are different from the classic target tissues for mineralocorticoid action, such as vascular cells. As judged from their time scale and insensitivity toward inhibitors of protein synthesis, effects are not mediated by the classic mineralocorticoid receptor pathway. Here we summarize studies on rapid in vitro aldosterone effects, e.

The human membrane progesterone receptor gene: genomic structure and promoter analysis.

Rapid, nongenomic effects of steroids are likely to be mediated by membrane receptors not by intracellular steroid receptors. We recently identified a progesterone membrane binding protein (mPR) from human liver. The corresponding hmpr gene is comprised of 3 exons and 2 introns.

Chemical modification and structural analysis of the progesterone membrane binding protein from porcine liver membranes.

In addition to the classical genomic steroid actions on modulation of transcription and protein synthesis, rapid, nongenomic effects have been described for various steroids. These effects on cellular signaling and function are supposed to be transmitted by membrane binding sites unrelated to the classical intracellular receptors. Recently, a high affinity progesterone membrane binding protein (mPR) has been characterized in porcine liver membranes.

Nongenomically initiated steroid actions.

The classical theory of steroid hormone action comprises binding to an intracellular receptor followed by modulation of transcriptional and translational events. These cumbersome model explains the characteristic latency of these genomic steroid effects. Over the past two decades, increasing evidence for rapid nongenomic effects of steroids, incompatible with the traditional model, has accumulated.

Multiple actions of steroid hormones--a focus on rapid, nongenomic effects.

According to the traditional model, steroid hormones bind to intracellular receptors and subsequently modulate transcription and protein synthesis, thus triggering genomic events finally responsible for delayed effects. Based upon similarities in molecular structure, specific receptors for steroids, vitamin D(3) derivatives, thyroid hormone, retinoids, and a variety of orphan receptors are considered to represent a superfamily of steroid receptors. In addition, very rapid effects of steroids mainly affecting intracellular signaling have been widely recognized that are clearly incompatible with the genomic model.

Nongenomic actions of steroids--from the laboratory to clinical implications.

In the classical concept of steroid action, steroids bind to cytoplasmic receptors and modulate nuclear transcription after translocation of steroid-receptor complexes into the nucleus. Due to similarities of molecular structure, receptors for steroids, retinoids, vitamin D3 and thyroid hormone are considered to represent a superfamily of receptors. While genomic steroid effects been evident for several decades, rapid effects of steroids have been characterized only recently.

Mannheim classification of nongenomically initiated (rapid) steroid action(s).

There is increasing evidence for rapid effects of steroids that are incompatible with the classical model of genomic steroid action. To address the diversity of mechanisms for rapid steroid signaling described over the past years, a classification of rapid steroid effects has been proposed to promote the discussion and understanding of nongenomic steroid action.

Specific nongenomic actions of aldosterone.

Background: According to the traditional model, steroid hormones modulate gene transcription and protein synthesis. The considerable latency of these genomic steroid effects is the consequence of these time-consuming steps of action. Over the years, it has become increasingly clear that rapid actions of steroids exist that are incompatible with this "classic" genomic model of action.

Rapid, nongenomic steroid actions: A new age?

In the traditional theory of steroid action, steroids bind to intracellular receptors and modulate nuclear transcription after translocation of steroid-receptor complexes into the nucleus. Due to similarities of molecular structure, specific receptors for steroids, vitamin D(3) derivatives, and thyroid hormone are considered to represent a superfamily of steroid receptors. While genomic steroid effects characterized by their delayed onset of action and their sensitivity to blockers of transcription and protein synthesis have been known for several decades, rapid actions of steroids have been more widely recognized and characterized in detail only recently.

Recognition of a human sperm surface protein involved in the progesterone-initiated acrosome reaction by antisera against an endomembrane progesterone binding protein from porcine liver.

Antisera against a porcine liver endomembrane progesterone (P4)-binding protein inhibited the P4-initiated acrosome reaction (AR) but not the ionomycin-initiated AR of human sperm. Indirect immunofluorescence studies detected antigen in the sperm head that moved during capacitation from a posterior head region to a midhead region. Moreover, the antisera detected a 44.